CN112134748A - Equipment state monitoring method, device, system and computer readable medium - Google Patents

Abstract

The invention provides an equipment state monitoring method, an equipment state monitoring device, an equipment state monitoring system and a computer readable medium, wherein the method comprises the following steps: acquiring a current monitoring equipment list based on the specified equipment type identifier; sending a request data packet to each monitoring device in the current monitoring device list, and enabling the monitoring devices to respond to the request data packet to read the state information through the target register address and package the state information to obtain a state information data packet; receiving the state information data packet, and performing exception handling on the received state information data packet to obtain a normal state information data packet; comparing the normal state information data packet with the reference state information data packet to obtain a comparison result; and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating the state information of the monitoring equipment according to the normal state information data packet. The invention can improve the equipment state monitoring efficiency and avoid unnecessary manpower consumption.

Description

Equipment state monitoring method, device, system and computer readable medium

Technical Field

The present invention relates to the field of device development and testing technologies, and in particular, to a device status monitoring method, a device status monitoring apparatus, a device status monitoring system, and a computer readable medium.

Background

With the refined development of the embedded equipment, more and more embedded equipment emerge in the market at present. However, over time, embedded devices suffer in all aspects of performance, and the processes relied upon during runtime can be problematic. Monitoring status information of the embedded device becomes particularly important.

At present, monitoring based on embedded equipment state information mainly aims at checking the problems of certain embedded equipment in the development and production process, quantitative real-time monitoring is not carried out on the embedded equipment, and the running state of the whole embedded equipment system is not comprehensively monitored. The incomplete monitoring method brings great inconvenience to production personnel, and how to effectively monitor the loss condition and the process state of the embedded equipment becomes a demand which needs to be met urgently.

Disclosure of Invention

Therefore, in order to solve the above-mentioned disadvantages, the present invention provides an apparatus status monitoring method, an apparatus status monitoring device, an apparatus status monitoring system, and a computer readable medium.

Specifically, in a first aspect, an embodiment of the present invention provides an apparatus state monitoring method, including: acquiring a current monitoring equipment list based on the specified equipment type identifier; sending a request data packet to each monitoring device in the current monitoring device list, and enabling the monitoring devices to respond to the request data packet to read state information through a target register address and package the state information to obtain a state information data packet; receiving the state information data packet, and performing exception handling on the received state information data packet to obtain a normal state information data packet; comparing the normal state information data packet with the reference state information data packet to obtain a comparison result; and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating the state information of the monitoring equipment according to the normal state information data packet.

In the prior art, the embedded device is not quantitatively monitored in real time, and the running state of the whole embedded device system is not comprehensively monitored. In the embodiment of the invention, the state information of the monitoring equipment is obtained by obtaining the monitoring equipment list, obtaining the state information data packet of each embedded equipment in the list, comparing the state information data packet with the reference state information data packet after carrying out exception processing on the state information data packet, the equipment generation process can be optimized, the abnormal condition of the equipment can be simply found, the condition that the equipment is not found to be abnormal in the equipment development and generation processes is avoided, the states of all the equipment in the same network and the custom monitoring range can be monitored simultaneously, no special requirement is required for the specific monitoring equipment, the type of the monitoring equipment can be customized, and the monitoring service has reference significance.

In an embodiment of the present invention, the obtaining the current monitoring device list based on the specified device type identifier includes: sending a device type request packet to be responded by each monitoring device to feed back a device type packet containing a device type identifier; and acquiring the equipment type identifier according to the received equipment type packet, screening the equipment type identifier based on the specified equipment type identifier, and adding the screened equipment type identifier to the current monitoring equipment list.

In an embodiment of the present invention, the receiving the status information packet and performing exception handling on the received status information packet to obtain a normal status information packet includes: judging whether the length of the state information data packet is smaller than the minimum length of the state information data packet or not; after judging that the length of the state information data packet is not less than the minimum length of the state information data packet, judging whether the position of a data packet header of the state information data packet is correct or not; and when the position of the data packet header is judged to be incorrect, searching the position of the data packet header and intercepting the state information data packet according to the effective length of the state information data packet to obtain the normal state information data packet.

In an embodiment of the present invention, after comparing the normal status information packet with the reference status information packet to obtain a comparison result, the method further includes: and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, replacing the reference state information data packet with the normal state information data packet to serve as a new reference state information data packet.

In an embodiment of the present invention, before the obtaining the current monitoring device list based on the specified device type identifier, the method further includes: sending a broadcast packet to be responded by each of the monitoring devices to feed back a response packet including an IP address; and acquiring the IP address according to the received response packet, and establishing point-to-point communication connection with each monitoring device based on the IP address.

In a second aspect, an embodiment of the present invention provides an apparatus for monitoring a device state, including: the list acquisition module is used for acquiring a current monitoring equipment list based on the specified equipment type identifier; a request sending module, configured to send a request data packet to each monitoring device in the current monitoring device list, so that the monitoring device responds to the request data packet to read status information through a target register address and package the status information to obtain a status information data packet; the exception handling module is used for receiving the state information data packet and carrying out exception handling on the received state information data packet to obtain a normal state information data packet; the data comparison module is used for comparing the normal state information data packet with the reference state information data packet to obtain a comparison result; and the information generation module is used for generating the state information of the monitoring equipment according to the normal state information data packet when the comparison result represents that the normal state information data packet is different from the reference state information data packet.

In the prior art, the embedded device is not quantitatively monitored in real time, and the running state of the whole embedded device system is not comprehensively monitored. In the embodiment of the invention, the state information of the monitoring equipment is obtained by obtaining the monitoring equipment list, obtaining the state information data packet of each embedded equipment in the list, comparing the state information data packet with the reference state information data packet after carrying out exception processing on the state information data packet, the equipment generation process can be optimized, the abnormal condition of the equipment can be simply found, the condition that the equipment is not found to be abnormal in the equipment development and generation processes is avoided, the states of all the equipment in the same network and the custom monitoring range can be monitored simultaneously, no special requirement is required for the specific monitoring equipment, the type of the monitoring equipment can be customized, and the monitoring service has reference significance.

In a third aspect, an embodiment of the present invention provides an apparatus state monitoring method, which is applied to monitoring apparatuses; the method comprises the following steps: receiving a broadcast packet, responding to the broadcast packet to feed back a response packet containing an IP address to a monitoring device, so that the monitoring device can obtain the IP address according to the response packet and establish point-to-point communication connection with the monitoring device according to the IP address; after the point-to-point communication connection is established, receiving a device type request packet, responding to the device type request packet to feed back a device type packet containing a device type identifier, so that the monitoring device can obtain the device type identifier according to the device type packet and add the device type identifier to a current monitoring device list; and after the device type identifier is added to the current monitoring device list, receiving a request data packet, responding to the request data packet to read state information through a target register address and packaging to obtain a state information data packet, and sending the state information data packet to the monitoring device so that the monitoring device can: carrying out exception processing on the state information data packet to obtain a normal state information data packet; comparing the normal state information data packet with the reference state information data packet to obtain a comparison result; and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating state information according to the normal state information data packet.

In the prior art, the embedded device is not quantitatively monitored in real time, and the running state of the whole embedded device system is not comprehensively monitored. In the embodiment of the invention, the monitoring equipment sends the state information data packet to the monitoring equipment, so that after the monitoring equipment carries out abnormal processing on the state information packet to obtain the normal state information packet, the normal state information packet is compared with the reference state information data packet to obtain the state information of the monitoring equipment, the workload of workers can be reduced, unnecessary consumption of the monitoring equipment in time and labor is reduced, the equipment generation process is optimized, meanwhile, the abnormal condition of the equipment can be simply found, the condition that the equipment is not found in time in the equipment development and generation processes is avoided, the states and the custom monitoring range of all equipment in the same network can be monitored simultaneously, no special requirement is required on the specific monitoring equipment, the type of the monitoring equipment can be custom-defined, and the monitoring equipment has reference significance for all monitoring services.

In a fourth aspect, an embodiment of the present invention provides an apparatus state monitoring device, which is applied to monitoring equipment, and includes: the monitoring equipment comprises a first process module, a second process module and a monitoring equipment, wherein the first process module is used for receiving a broadcast packet, responding to the broadcast packet and feeding back a response packet containing an IP address to the monitoring equipment so that the monitoring equipment can obtain the IP address according to the response packet and establish point-to-point communication connection with the monitoring equipment according to the IP address; the second process module is used for receiving an equipment type request packet after the point-to-point communication connection is established, responding to the equipment type request packet to feed back an equipment type packet containing an equipment type identifier, so that the monitoring equipment can obtain the equipment type identifier according to the equipment type packet and add the equipment type identifier to a current monitoring equipment list; a third process module, configured to receive a request data packet after the device type identifier is added to the current monitoring device list, respond to the request data packet to read status information through a destination register address and package the status information to obtain a status information data packet, and send the status information data packet to the monitoring device, so that the monitoring device: carrying out exception processing on the state information data packet to obtain a normal state information data packet; comparing the normal state information data packet with the reference state information data packet to obtain a comparison result; and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating state information according to the normal state information data packet.

In the prior art, the embedded device is not quantitatively monitored in real time, and the running state of the whole embedded device system is not comprehensively monitored. In the embodiment of the invention, the monitoring equipment sends the state information data packet to the monitoring equipment, so that after the monitoring equipment carries out abnormal processing on the state information packet to obtain the normal state information packet, the normal state information packet is compared with the reference state information data packet to obtain the state information of the monitoring equipment, the workload of workers can be reduced, unnecessary consumption of the monitoring equipment in time and labor is reduced, the equipment generation process is optimized, meanwhile, the abnormal condition of the equipment can be simply found, the condition that the equipment is not found in time in the equipment development and generation processes is avoided, the states and the custom monitoring range of all equipment in the same network can be monitored simultaneously, no special requirement is required on the specific monitoring equipment, the type of the monitoring equipment can be custom-defined, and the monitoring equipment has reference significance for all monitoring services.

In a fifth aspect, an embodiment of the present invention provides an apparatus status monitoring system, including: a monitoring device and a plurality of monitoring devices connected to the monitoring device; wherein the monitoring device is configured to perform a device condition monitoring method as defined in any one of the preceding claims.

In a sixth aspect, an embodiment of the present invention provides a computer-readable medium, where a program code is stored, where the program code includes instructions for executing the device status monitoring method according to any one of the foregoing descriptions.

As can be seen from the above, the embodiments of the present invention can achieve one or more of the following advantages: 1) the workload of workers is reduced, unnecessary consumption of monitoring equipment in time and labor is reduced, and the equipment generation process is optimized; 2) the abnormal conditions of the equipment can be concisely discovered, and the condition that the equipment is not discovered in time in the development and generation processes of the equipment is avoided; 3) the state and the customized monitoring range of all the devices in the same network can be monitored simultaneously, no special requirement is required on the specific monitoring devices, the types of the monitoring devices can be customized, and the reference significance is provided for all the monitoring services; and 4) the state information has larger definition range and more comprehensive monitoring.

Other aspects and features of the present invention will become apparent from the following detailed description, which proceeds with reference to the accompanying drawings. It is to be understood, however, that the drawings are designed solely for purposes of illustration and not as a definition of the limits of the invention. It should be further understood that the drawings are not necessarily drawn to scale and that, unless otherwise indicated, they are merely intended to conceptually illustrate the structures and procedures described herein.

Drawings

The following detailed description of embodiments of the invention will be made with reference to the accompanying drawings.

Fig. 1 is a flowchart illustrating a method for monitoring a device status according to a first embodiment of the present invention;

fig. 2 is a flowchart of step S11 in an apparatus condition monitoring method according to a first embodiment of the present invention;

fig. 3 is a flowchart of step S13 in an apparatus condition monitoring method according to a first embodiment of the present invention;

fig. 4 is a flowchart illustrating steps further included after step S14 in an apparatus condition monitoring method according to a first embodiment of the present invention;

fig. 5 is a flowchart illustrating steps included in a device condition monitoring method according to a first embodiment of the present invention before step S11;

fig. 6 is a schematic structural diagram of an equipment state monitoring system according to a specific implementation of an equipment state monitoring method according to a first embodiment of the present invention;

fig. 7 is a schematic flowchart of a specific implementation of a device status monitoring method according to a first embodiment of the present invention;

fig. 8 is a schematic flowchart illustrating a process of processing a data packet by a monitoring tool in an embodiment of a device status monitoring method according to a first embodiment of the present invention;

fig. 9 is a schematic structural diagram of an apparatus state monitoring device according to a second embodiment of the present invention;

fig. 10 is a flowchart illustrating a method for monitoring a device status according to a third embodiment of the present invention;

fig. 11 is a schematic flowchart of a step S43 in an apparatus condition monitoring method according to a third embodiment of the present invention;

fig. 12 is a schematic structural diagram of an apparatus state monitoring device according to a fourth embodiment of the present invention;

fig. 13 is a schematic structural diagram of an apparatus condition monitoring system according to a fifth embodiment of the present invention;

fig. 14 is a schematic structural diagram of a computer-readable medium according to a sixth embodiment of the present invention.

[ description of reference ]

S11-S16, S111-S112, S131-S133, S101-S102: monitoring the equipment state;

30: a device state monitoring device; 31: a list acquisition module; 32: a request sending module; 33: an exception handling module; 34: a data comparison module; 35: an information generation module;

S41-S43, S431-S433: monitoring the equipment state;

50: a device state monitoring device; 51: a first process module; 52: a second process module; 53: a third process module;

60: an equipment status monitoring system; 61: monitoring equipment; 62: monitoring equipment;

70: a computer readable medium.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In order to make those skilled in the art better understand the technical solution of the present invention, the technical solution in the embodiment of the present invention will be clearly and completely described below with reference to the drawings in the embodiment of the present invention, and it is obvious that the described embodiment is only a part of the embodiment of the present invention, and not a whole embodiment. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the terms so used are interchangeable under appropriate circumstances such that the embodiments of the invention described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

[ first embodiment ] A method for manufacturing a semiconductor device

Referring to fig. 1, a first embodiment of the present invention provides a device condition monitoring method. As shown in fig. 1, the apparatus state monitoring method includes, for example, steps S11 to S15.

Step S11: acquiring a current monitoring equipment list based on the specified equipment type identifier;

step S12: sending a request data packet to each monitoring device in the current monitoring device list, and enabling the monitoring devices to respond to the request data packet to read state information through a target register address and package the state information to obtain a state information data packet;

step S13: receiving the state information data packet, and performing exception handling on the received state information data packet to obtain a normal state information data packet;

step S14: comparing the normal state information data packet with the reference state information data packet to obtain a comparison result;

step S15: and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating the state information of the monitoring equipment according to the normal state information data packet.

Further, as shown in fig. 2, step S11 includes, for example, step S111 and step S112.

Step S111: sending a device type request packet to be responded by each monitoring device to feed back a device type packet containing a device type identifier;

step S112: and acquiring the equipment type identifier according to the received equipment type packet, screening the equipment type identifier based on the specified equipment type identifier, and adding the screened equipment type identifier to the current monitoring equipment list.

In particular, the monitoring device is, for example, an embedded device, such as, for example, a sending card or a receiving card. The format of the device type request packet referred to includes, for example, a header, an address, a valid data length, a data field, and a check bit. The device type identifier mentioned is for example an identification code of the associated monitoring device. The status information mentioned in step S12 includes, for example, status data and version information. Wherein the status data for example comprises: master control card temperature, programmable logic device temperature, master fan state, programmable logic device fan state, port state, input source state, network state, USB state, and window state. The mentioned status data may also include status information such as Logo and bkg, for example. The version information includes, for example, a software version number and a hardware process version number. The state data and version information correspond to different target register addresses, for example. And the status information packet referred to in step S12 includes, for example, a status packet and a version information packet.

Further, as shown in fig. 3, step S13 includes, for example, step S131 to step S133.

Step S131: judging whether the length of the state information data packet is smaller than the minimum length of the state information data packet or not;

step S132: after judging that the length of the state information data packet is not less than the minimum length of the state information data packet, judging whether the position of a data packet header of the state information data packet is correct or not;

step S133: and when the position of the data packet header is judged to be incorrect, searching the position of the data packet header and intercepting the state information data packet according to the effective length of the state information data packet to obtain the normal state information data packet.

Specifically, in step S13, the received status information packet may be an abnormal packet, so it is necessary to determine the status information packet and process the abnormal packet. The exception packet includes, for example: the length of the data packet is smaller than the minimum length of the data packet and the dislocation of the data packet head. The packet header misalignment includes, for example: the data packet header is located at the center of the data packet and the data packet header is located in the next data packet. And directly deleting the data packet with the data packet length smaller than the minimum data packet length. And circularly searching the position of the data packet header for the data packet with the misplaced data packet header, and then intercepting according to the length of the data packet to obtain the normal state information data packet. The reference status information packet referred to in step S14 is, for example, a normal status information packet stored via the last status monitoring flow. By carrying out abnormity judgment on the state information data packet and processing the abnormal data packet, the influence of the obtained abnormal data packet on the detection result can be avoided, and the accuracy of the detection result is ensured.

Further, as shown in fig. 4, step S16 is also included after step S14, for example.

Step S16: and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, replacing the reference state information data packet with the normal state information data packet to serve as a new reference state information data packet.

Specifically, the reference state information data packet is used for judging whether the state information of the currently input normal state information data packet changes, and each comparison is performed by referring to the last normal state information data packet, so that the two data packets are found to be different after comparison, and the current normal state information data packet is stored and replaced with the original reference state information data packet to serve as a parameter state information data packet for the next comparison.

Further, as shown in fig. 5, step S101 and step S102 are also included before step S11.

Step S101: sending a broadcast packet to be responded by each of the monitoring devices to feed back a response packet including an IP address;

step S102: and acquiring the IP address according to the received response packet, and establishing point-to-point communication connection with each monitoring device based on the IP address.

The point-to-point communication mentioned is, for example, TCP communication.

It should be noted that the present embodiment does not limit the sequence of step S15 and step S16, and step S16 may be located after step S15, or before step S15, or may be performed simultaneously. In addition, step S12 may also be the case when the connection is initially established, where the request packet at this time is equivalent to a data reception preparation signal to inform the monitoring device that the status information packet can be sent out, and the monitoring device can periodically and actively send out the status information packet in each subsequent monitoring process without responding to the request packet again. Or a button is arranged on the monitoring equipment, and the working personnel sends UDP broadcast once when pressing once.

For better understanding of the present embodiment, a detailed description of the present embodiment is provided below with reference to fig. 6 to 8.

Fig. 6 is a schematic structural diagram of an equipment aging system adopted in the embodiment of this embodiment. As shown in fig. 6, a plurality of monitoring apparatuses 1 to n participating in the apparatus state monitoring are connected to a monitoring computer via a network. Each monitoring device 1-n establishes TCP communication with the monitoring computer, and if the monitoring device 1-n or the monitoring computer needs to be accessed to the wide area network, the monitoring device can be connected with the wide area network interface through the switch.

Fig. 7 is a flow chart illustrating an embodiment of the present invention. Wherein, the monitoring tool process is arranged in the monitoring computer. A tmd process, a p2pd process and a diagd process are provided in each monitoring device. The diagd process, namely the equipment state monitoring, is executed by using a script, and is mainly in data communication with the monitoring tool process. The p2pd process, a device connection and identification process, is also known as a peer-to-peer process, and is used to manage the types of devices that need to be monitored. the tmd process is a device broadcast reply process for detecting whether the process program state is alive. The specific implementation steps are described in detail below with reference to fig. 7.

a) Firstly, monitoring tool processes of a monitoring computer send UDP broadcasts, tmd processes of each monitoring device respond to the UDP broadcasts and send response packets;

specifically, the monitoring tool process sets the REQUEST _ STRING constant STRING, which can be set according to actual conditions. Then, initializing to send broadcast by adopting initBroadcast (), and realizing one-minute broadcast detection of monitoring equipment in the same local area network by utilizing a timer so as to circularly obtain all monitoring equipment in the current local area network.

b) The monitoring tool process of the monitoring computer sends an address request to acquire the IP address of the response monitoring equipment, and after TCP connection is established with the p2pd process of the monitoring equipment according to the IP address, an equipment type request packet is sent to send the equipment type packet by the p2pd process of the monitoring equipment. The equipment type package comprises a ModelID (equipment type identifier) of the monitoring equipment, and a monitoring tool process of the monitoring computer can screen the ModelID through the equipment identifier of the specified type to obtain the monitoring equipment of the specified type;

specifically, a packet receiving processing slot _ readudp data () in the monitoring tool process receives an IP address sent by the monitoring device, then establishes a TCP connection with the monitoring device according to the IP address, sends a device type request packet according to a specified packet format (a data packet header, an address, an effective data length, a data area, and a check bit), receives a device type packet sent by the monitoring device in response to the device type request packet, and determines whether the obtained monitoring device is the specified type monitoring device according to a device type identifier in the device type packet.

c) And the monitoring tool process adds the screened monitoring equipment to the current monitoring equipment list so as to avoid receiving other data packets sent by the monitoring equipment which do not meet the requirement.

d) And the monitoring tool process sends a request data packet to the diagd process of the monitoring equipment in the monitoring equipment list.

e) And the diagd process of the monitoring equipment responds to the request data packet and sends a state information data packet to the monitoring tool process. And the monitoring tool process determines the type of the received data packet according to the address, the length of the data packet and the check bit in the received state information data packet and processes the data packet so as to monitor the state of the monitoring equipment in real time and count to obtain the normal and abnormal conditions of the monitoring equipment.

Specifically, the diagd process of the monitoring device reads the current hardware device state through the register address of the bottom circuit board and pushes the current hardware device state in real time. The diagd process can obtain device state data, and the device state data mainly includes real-time updating and detection of states such as a master control card temperature, an FPGA temperature, a main fan state, an FPGA fan state, a network port state, an input source state, a window state, a network state, a USB state, a logo, a bkg state and the like. The network port status is, for example, online or offline. The input source status shows, for example, whether the current input source has an input signal. The window state is, for example, open or closed. USB situations are for example insertion or removal, etc. In addition, the diagd process may also monitor general parameters of the device, i.e., version information, for example, a current monitoring device carries a software version number and a version number of the hardware process.

As shown in fig. 8, the specific steps of receiving and processing the data packet by the monitoring tool process are as follows:

(1) after receiving the status information data packet, the monitoring tool process saves the data packet, i.e., adds the data packet to the queue. And then, exception handling is carried out on the data packet, so that the monitoring is prevented from being influenced by the exception of the data packet.

The abnormal types of the data packets are mainly divided into three types, namely (i) the length of the data packet is smaller than the minimum length; the head of the data packet is positioned in the center of the data packet; and thirdly, the data packet head is positioned in the next packet of data. The three abnormal conditions are all processed, and the main implementation scheme of the whole processing process is as follows:

(i) discarding the data packet with the data packet length smaller than the minimum data packet length;

(ii) judging whether the head of the data packet is the beginning of AA55, if not, searching the position of the head, intercepting the data packet, wherein the intercepted length is the effective length of the data packet, and checking the check bit by a matchCountCRC method to determine whether the data packet is correct;

(iii) loop (ii) stops looping until the data pointer location points to-1 to get a normal state information packet.

(2) The monitoring tool process judges whether the state information in the normal state information data packet changes according to the reference state information data packet, if the two data packets are different, the state information is judged to change, and the next step is carried out. The reference status information packet is a normal status information packet stored in the last status monitoring process. In addition, when the data packets are judged to be different, the current normal state information data packet is stored in place of the reference state information data packet to serve as the reference state information data packet of the next state monitoring process.

(3) The monitoring tool process distinguishes the type of the normal state information data packet according to the address, namely the version information packet or the state data packet. For example, a set of data type flags is agreed between the diagd process and the monitoring tool process, and the monitoring tool process can determine the type of the data packet according to the agreed data type flags. The data category flags are as follows:

# define EQUIP _ TYPE 0x02// device TYPE packet;

# define SOFT _ VER 0xEEEEEE03// equipment version information package;

# define EQUIP _ STATUS 0x003// device STATUS packet.

(4) After the monitoring tool process distinguishes the types of the normal state information data packets, whether the data packets are the equipment data in the current monitoring equipment list or not is judged, and after the judgment is yes, the corresponding data is processed.

Specifically, the monitoring tool process processes the data packet sent by the corresponding monitoring device according to the device IP. Taking the process state as an example, firstly, the monitoring tool process obtains the running state in the bottom layer process in real time, and the state is divided into three types: (-) online (0x 01); ②ine (0x 02); ③ undef (0x 03). Then, the monitoring tool process will detect whether the process is abnormal: if the state is 0x02 or 0x03, the process is abnormal. And finally, the monitoring tool process can count the normal and abnormal conditions of the monitoring equipment, and calculate the total number condition to refresh in real time.

The monitoring range of the equipment state monitoring method provided by the embodiment of the invention can be customized according to users, has no special requirements on specific monitoring equipment, and has reference function on all monitoring services. Firstly, the information of the traditional monitoring equipment is expanded to the level of equipment dependent process, and an achievable technical scheme is provided for the purpose; secondly, the equipment monitoring method can be applied to wider fields, can test a large amount of equipment and plays a greater role; thirdly, the types of the monitoring devices can be defined according to the requirements of the monitoring devices, and one type, two types or three types of monitoring devices can be simultaneously monitored. In addition, common production personnel can simply and simply discover the abnormality of the monitoring equipment, the problem that the equipment state cannot be found in time in the equipment development and production process is avoided, unnecessary consumption is reduced in time and labor, and the production process is optimized.

[ second embodiment ]

Referring to fig. 9, a second embodiment of the present invention provides an apparatus condition monitoring device. As shown in fig. 9, the device status monitoring apparatus 30 includes, for example, a list acquisition module 31, a request transmission module 32, an exception handling module 33, a data comparison module 34, and an information generation module 35.

The list obtaining module 31 is configured to obtain a current monitoring device list based on the specified device type identifier. The request sending module 32 is configured to send a request data packet to each monitoring device in the current monitoring device list, so that the monitoring device responds to the request data packet to read status information through a destination register address and package the status information to obtain a status information data packet. The exception handling module 33 is configured to receive the status information data packet, and perform exception handling on the received status information data packet to obtain a normal status information data packet. The data comparison module 34 is configured to compare the normal state information data packet with the reference state information data packet to obtain a comparison result. The information generating module 35 is configured to generate the status information of the monitoring device according to the normal status information packet when the comparison result indicates that the normal status information packet is different from the reference status information packet.

It should be noted that the method for monitoring the state of the device implemented by the device state monitoring apparatus 30 in this embodiment is as described in the first embodiment, and therefore, the detailed description thereof is omitted. Optionally, each module and the other operations or functions in the second embodiment are respectively for implementing the method in the first embodiment of the present invention, and are not described herein for brevity. The technical effect of the device status monitoring apparatus 30 provided in this embodiment is the same as that of the device status monitoring method in the first embodiment, and is not described herein again.

[ third embodiment ]

As shown in fig. 10, a third embodiment of the present invention provides a device status monitoring method. As shown in fig. 10, the apparatus state monitoring method includes, for example, steps S41 to S43.

Step S41: receiving a broadcast packet, responding to the broadcast packet to feed back a response packet containing an IP address to a monitoring device, so that the monitoring device can obtain the IP address according to the response packet and establish point-to-point communication connection with the monitoring device according to the IP address;

step S42: after the point-to-point communication connection is established, receiving a device type request packet, responding to the device type request packet to feed back a device type packet containing a device type identifier, so that the monitoring device can obtain the device type identifier according to the device type packet and add the device type identifier to a current monitoring device list; and

step S43: after the device type identifier is added to the current monitoring device list, a request packet is received, a status information packet is obtained by responding to the request packet and reading status information through a destination register address and packaging the status information packet, and the status information packet is sent to the monitoring device, so that the monitoring device can perform steps S431 to S433, for example, see fig. 11.

Step S431: carrying out exception processing on the state information data packet to obtain a normal state information data packet;

step S432: comparing the normal state information data packet with the reference state information data packet to obtain a comparison result;

step S433: and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating state information according to the normal state information data packet.

Specifically, the monitoring device is, for example, a personal computer or the like having monitoring software installed therein, that is, the monitoring computer mentioned in the first embodiment. The mentioned point-to-point communication is for example TCP communication. The format of the device type request packet referred to includes, for example, a header, an address, a valid data length, a data field, and a check bit. The device type identifier mentioned is for example an identification code of the associated monitoring device. The status information mentioned in step S12 includes, for example, status data and version information. Wherein the status data for example comprises: master control card temperature, programmable logic device temperature, master fan state, programmable logic device fan state, port state, input source state, network state, USB state, and window state. The mentioned status data may also include status information such as Logo and bkg, for example. The version information includes, for example, a software version number and a hardware process version number. The state data and version information correspond to different target register addresses, for example. The mentioned status information packets include, for example, status packets and version packets. In addition, the mentioned processes of exception handling and packet comparison for the packet may refer to the first embodiment, and for brevity, are not described herein again.

It should be noted that the equipment state monitoring method according to the third embodiment of the present invention is described from the perspective of monitoring equipment, while the equipment state monitoring method according to the foregoing first embodiment of the present invention is described from the perspective of monitoring equipment, i.e., monitoring computer, the methods involved in the two embodiments are only different in subject, and the involved steps can be referred to each other.

The monitoring range of the equipment state monitoring method provided by the embodiment of the invention can be customized according to users, has no special requirements on specific monitoring equipment, and has reference function on all monitoring services. Firstly, the information of the traditional monitoring equipment is expanded to the level of equipment dependent process, and an achievable technical scheme is provided for the purpose; secondly, the equipment monitoring method can be applied to wider fields, can test a large amount of equipment and plays a greater role; thirdly, the types of the monitoring devices can be defined according to the requirements of the monitoring devices, and one type, two types or three types of monitoring devices can be simultaneously monitored. In addition, common production personnel can simply and simply discover the abnormality of the monitoring equipment, the problem that the equipment state cannot be found in time in the equipment development and production process is avoided, unnecessary consumption is reduced in time and labor, and the production process is optimized.

[ fourth example ] A

As shown in fig. 12, a fourth embodiment of the present invention provides an apparatus state monitoring device. As shown in fig. 12, the device condition monitoring apparatus 50 includes, for example: a first process module 51, a second process module 52 and a third process module 53.

The first process module 51 is configured to receive a broadcast packet, respond to the broadcast packet, and feed back a response packet including an IP address to the monitoring device, so that the monitoring device obtains the IP address according to the response packet, and establish a peer-to-peer communication connection with the monitoring device according to the IP address. The second process module 52 is configured to receive a device type request packet after the peer-to-peer communication connection is established, and respond to the device type request packet to feed back a device type packet including a device type identifier, so that the monitoring device obtains the device type identifier according to the device type packet, and adds the device type identifier to a current monitoring device list. The third process module 53 is configured to receive a request data packet after the device type identifier is added to the current monitoring device list, respond to the request data packet to read status information through a destination register address and package the status information to obtain a status information data packet, and send the status information data packet to the monitoring device, so that the monitoring device: carrying out exception processing on the state information data packet to obtain a normal state information data packet; comparing the normal state information data packet with the reference state information data packet to obtain a comparison result; and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating state information according to the normal state information data packet.

The first process module 51 in this embodiment corresponds to the tmd process mentioned in the first embodiment. The second process module 52 corresponds to, for example, the p2pd process mentioned in the first embodiment. The third process module 53 corresponds for example to the diagd process mentioned in the first embodiment. For the introduction of the functions of the modules, reference may be made to the first embodiment, which is not described herein again.

It should be noted that the method for monitoring the state of the device implemented by the device state monitoring apparatus 50 in this embodiment is as described in the third embodiment, and therefore, the detailed description thereof is omitted. Optionally, each module and the other operations or functions in the fourth embodiment are respectively for implementing the method in the third embodiment of the present invention, and are not described herein for brevity. The technical effect of the device status monitoring apparatus 50 provided in this embodiment is the same as that of the device status monitoring method in the third embodiment, and is not described herein again.

[ fifth embodiment ]

Referring to fig. 13, a fifth embodiment of the present invention provides an apparatus condition monitoring system. As shown in fig. 13, the device condition monitoring system 60 includes, for example: a monitoring device 61 and a plurality of monitoring devices 62 connected to the monitoring device 61. For example, fig. 13 illustrates 4 monitoring devices, but the invention is not limited thereto. The monitoring device 61 is configured to perform the device status monitoring method according to the first embodiment. For example, the monitoring device 61 performs the following steps:

(i) acquiring a current monitoring equipment list based on the specified equipment type identifier;

(ii) sending a request data packet to each monitoring device in the current monitoring device list, and enabling the monitoring devices to respond to the request data packet to read state information through a target register address and package the state information to obtain a state information data packet;

(iii) receiving the state information data packet, and performing exception handling on the received state information data packet to obtain a normal state information data packet;

(iv) comparing the normal state information data packet with the reference state information data packet to obtain a comparison result;

(v) and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating the state information of the monitoring equipment according to the normal state information data packet.

It should be noted that, for the sake of brevity, the method for monitoring the state of the device implemented by the device state monitoring system provided in this embodiment is as described in the foregoing first embodiment, and therefore, a detailed description thereof is not provided herein. Specifically, the monitoring device 61 is, for example, a device such as a personal computer, which is installed with relevant monitoring software, that is, the monitoring computer mentioned in the first embodiment. The monitoring device 62 is mentioned as an embedded device, for example a sending card or a receiving card, etc. A TCP connection is for example between the monitoring device 61 and the monitoring device 62.

In summary, the equipment state monitoring system provided by the embodiment of the invention reduces the workload of workers, reduces unnecessary consumption of monitoring equipment in time and labor, and optimizes the equipment generation process; the abnormal conditions of the equipment can be concisely discovered, and the condition that the equipment is not discovered in time in the development and generation processes of the equipment is avoided; the state and the customized monitoring range of all the devices in the same network can be monitored simultaneously, no special requirement is required on the specific monitoring devices, the types of the monitoring devices can be customized, and the reference significance is provided for all the monitoring services; and the definition range of the state information is larger, and the monitoring is more comprehensive.

[ sixth embodiment ]

Referring to fig. 14, a sixth embodiment of the present invention provides a computer-readable medium. As shown in fig. 14, the computer-readable medium 70 stores a program code including instructions for executing the device state monitoring method according to the first embodiment or the third embodiment. For example, the program code is such as instructions to perform the steps of:

(i) acquiring a current monitoring equipment list based on the specified equipment type identifier;

(ii) sending a request data packet to each monitoring device in the current monitoring device list, and enabling the monitoring devices to respond to the request data packet to read state information through a target register address and package the state information to obtain a state information data packet;

(iii) receiving the state information data packet, and performing exception handling on the received state information data packet to obtain a normal state information data packet;

(iv) comparing the normal state information data packet with the reference state information data packet to obtain a comparison result;

(v) and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating the state information of the monitoring equipment according to the normal state information data packet.

The program code of the computer readable medium 70 provided in this embodiment executes the apparatus status monitoring method as described in the first embodiment or the third embodiment, so that detailed description thereof is omitted. Optionally, the computer readable medium 70 in this embodiment is not described herein for brevity in order to implement the method in the first embodiment or the third embodiment of the present invention. The technical effect of the computer-readable medium 70 provided in this embodiment is the same as that of the device status monitoring method in the first embodiment or the third embodiment, and is not described herein again.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. A method for monitoring a condition of a device, comprising:

acquiring a current monitoring equipment list based on the specified equipment type identifier;

sending a request data packet to each monitoring device in the current monitoring device list, and enabling the monitoring devices to respond to the request data packet to read state information through a target register address and package the state information to obtain a state information data packet;

receiving the state information data packet, and performing exception handling on the received state information data packet to obtain a normal state information data packet;

comparing the normal state information data packet with the reference state information data packet to obtain a comparison result;

and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating the state information of the monitoring equipment according to the normal state information data packet.

2. The device status monitoring method according to claim 1, wherein the obtaining the current monitoring device list based on the specified device type identifier comprises:

sending a device type request packet to be responded by each monitoring device to feed back a device type packet containing a device type identifier;

and acquiring the equipment type identifier according to the received equipment type packet, screening the equipment type identifier based on the specified equipment type identifier, and adding the screened equipment type identifier to the current monitoring equipment list.

3. The device status monitoring method according to claim 1, wherein the receiving the status information packet and performing exception handling on the received status information packet to obtain a normal status information packet comprises:

judging whether the length of the state information data packet is smaller than the minimum length of the state information data packet or not;

after judging that the length of the state information data packet is not less than the minimum length of the state information data packet, judging whether the position of a data packet header of the state information data packet is correct or not;

and when the position of the data packet header is judged to be incorrect, searching the position of the data packet header and intercepting the state information data packet according to the effective length of the state information data packet to obtain the normal state information data packet.

4. The device status monitoring method according to claim 1, wherein after comparing the normal status information packet with the reference status information packet to obtain a comparison result, the method further comprises:

and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, replacing the reference state information data packet with the normal state information data packet to serve as a new reference state information data packet.

5. The device status monitoring method according to claim 1, further comprising, before the obtaining the current monitoring device list based on the specified device type identifier:

sending a broadcast packet to be responded by each of the monitoring devices to feed back a response packet including an IP address;

and acquiring the IP address according to the received response packet, and establishing point-to-point communication connection with each monitoring device based on the IP address.

6. An apparatus condition monitoring device, comprising:

the list acquisition module is used for acquiring a current monitoring equipment list based on the specified equipment type identifier;

a request sending module, configured to send a request data packet to each monitoring device in the current monitoring device list, so that the monitoring device responds to the request data packet to read status information through a target register address and package the status information to obtain a status information data packet;

the exception handling module is used for receiving the state information data packet and carrying out exception handling on the received state information data packet to obtain a normal state information data packet;

the data comparison module is used for comparing the normal state information data packet with the reference state information data packet to obtain a comparison result;

and the information generation module is used for generating the state information of the monitoring equipment according to the normal state information data packet when the comparison result represents that the normal state information data packet is different from the reference state information data packet.

7. An equipment state monitoring method is applied to monitoring equipment; it is characterized by comprising:

receiving a broadcast packet, responding to the broadcast packet to feed back a response packet containing an IP address to a monitoring device, so that the monitoring device can obtain the IP address according to the response packet and establish point-to-point communication connection with the monitoring device according to the IP address;

after the point-to-point communication connection is established, receiving a device type request packet, responding to the device type request packet to feed back a device type packet containing a device type identifier, so that the monitoring device can obtain the device type identifier according to the device type packet and add the device type identifier to a current monitoring device list; and

after the device type identifier is added to the current monitoring device list, receiving a request data packet, responding to the request data packet to read state information through a target register address and packaging the state information to obtain a state information data packet, and sending the state information data packet to the monitoring device so that the monitoring device can:

carrying out exception processing on the state information data packet to obtain a normal state information data packet;

comparing the normal state information data packet with the reference state information data packet to obtain a comparison result;

and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating state information according to the normal state information data packet.

8. The utility model provides an equipment condition monitoring devices, is applied to monitoring facilities, its characterized in that includes:

the monitoring equipment comprises a first process module, a second process module and a monitoring equipment, wherein the first process module is used for receiving a broadcast packet, responding to the broadcast packet and feeding back a response packet containing an IP address to the monitoring equipment so that the monitoring equipment can obtain the IP address according to the response packet and establish point-to-point communication connection with the monitoring equipment according to the IP address;

the second process module is used for receiving an equipment type request packet after the point-to-point communication connection is established, responding to the equipment type request packet to feed back an equipment type packet containing an equipment type identifier, so that the monitoring equipment can obtain the equipment type identifier according to the equipment type packet and add the equipment type identifier to a current monitoring equipment list;

a third process module, configured to receive a request data packet after the device type identifier is added to the current monitoring device list, respond to the request data packet to read status information through a destination register address and package the status information to obtain a status information data packet, and send the status information data packet to the monitoring device, so that the monitoring device: carrying out exception processing on the state information data packet to obtain a normal state information data packet; comparing the normal state information data packet with the reference state information data packet to obtain a comparison result; and when the comparison result represents that the normal state information data packet is different from the reference state information data packet, generating state information according to the normal state information data packet.

9. An equipment condition monitoring system, comprising: a monitoring device and a plurality of monitoring devices connected to the monitoring device; wherein the monitoring device is configured to perform the device status monitoring method according to any one of claims 1 to 5.

10. A computer-readable medium, characterized in that the computer-readable medium stores a program code comprising instructions for performing the device status monitoring method according to any one of claims 1-5 and claim 7.

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